JP4384440B2 - Dye complex and aqueous composition containing the same - Google Patents

Description

【００２１】
表１から明らかなように、酸性染料ＲＢ単独の水溶液に比べて、本発明の染料複合化粘土鉱物（RB/PVP/LA−１）の水溶液の方が、ΔＥ_Ｘ−０値が小さく、耐塩素性に優れていることが理解される。
また、そのＬ値から解るように、本発明の酸性染料複合化粘土鉱物の水溶液は、各コントロールと同様にほぼ１００％であり、透明性が非常に高いものであった。また、発色も非常に良好であった。
【００２２】
配合例１ 化粧水
（１）イオン交換水 残余
（２）エタノール １０
（３）ジプロピレングリコール １０
（４）ＰＥＧ１５００ ５
（５）POE(20)オレイルアルコールエーテル ０．５
（６）メチルセルロース ０．３
（７）防腐剤 ０．２
（８）キレート剤 ０．０１
（９）香料 適量
（10）BB/PVP/La−１ ０．０１
【００２３】
（製法）
3、４、６、8を1の一部に分散させた後、これに、2に溶解させた5、7、９を添加した。10を1の残余に分散させて、透明になるまで攪拌して得られた着色液を前記混合液に添加して調色後、ろ過して化粧水を得た。
【００２４】
配合例２ 乳液

【００２５】
（製法）
イオン交換水の一部に保湿剤部と防腐剤を加熱溶解したものと高分子部を加えて室温で溶解する。これに中和剤を加えたものを水相部とする。これに室温で均一混合した油分、酸化防止剤、香料を添加して、ホモミキサーを用いて乳化する。その後、あらかじめイオン交換水残部にタートラジン/PDDA/Laを分散させることにより得られた、透明な着色水を乳化物に添加し、攪拌混合することで調色を行い、その後、脱気、ろ過を行い乳液を得た。
【００２６】
【発明の効果】
本発明によれば、水膨潤性粘土鉱物に非イオン性親水性高分子と水溶性酸性染料とを複合化した染料複合化粘土鉱物が得られ、該染料複合化粘土鉱物は、着色性、透明性、耐塩素性等に優れ、水系組成物の着色剤として有用である。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a dye complex and a composition containing the same, and more particularly to improvement of chlorine resistance of the dye complex.
[0002]
[Prior art]
Water-swellable clay minerals are known to form complexes with various organic compounds. In other words, the water-swellable clay mineral has a structure in which plate-like crystals are stacked and have cations and water molecules between layers, so that other molecules are included by intercalation with cations or water molecules between layers (intercalation). And can easily be made into a composite. Thus, the water-swellable clay mineral can impart various functions by forming a complex with various functional molecules.
On the other hand, water-soluble dyes such as acid dyes and basic dyes are used for various coloring applications such as cosmetics because of their vivid color, but they are vulnerable to external factors such as chlorine resistance in water. Many.
As a complex of a pigment and a water-swellable clay mineral, for example, Patent Document 1 reports that a pigment having good dispersibility can be obtained by adsorbing a pigment to a complex of chitosan and swellable smectite. ing. Patent Document 2 reports that a complex of a dye, a linear polycation having no cyclic sugar structure, and a layered clay mineral is excellent in light resistance, elution resistance, and the like.
[0003]
[Patent Document 1]
Japanese Patent Laid-Open No. 3-139568 [Patent Document 2]
Japanese Patent Laid-Open No. 11-116837
[Problems to be solved by the invention]
However, in order to use chitosan dissolved, it is necessary to use a solvent having an acidic pH, and usable dyes are limited. The polycation used in Patent Document 2 is also of an amine type having a primary amino group such as polyethyleneimine, and is considered to be affected by pH. Further, in any case, there are problems such as insufficient pigment content in the pigment, or fine pulverization in order to sufficiently exert the coloring power. Furthermore, these pigments have a problem of dispersibility in water, and it has been difficult to use them as substitutes for acid dyes.
The present invention has been made in view of the above-described problems of the prior art, and an object thereof is to provide an aqueous colorant excellent in colorability, transparency and chlorine resistance in water, and a colored aqueous composition containing the same. There is.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, the present inventors have conducted intensive studies. As a result, a dye-complexed clay mineral in which a water-swellable clay mineral is combined with a nonionic hydrophilic polymer and a water-soluble acidic dye. However, the present inventors have found that it is excellent in colorability, transparency and chlorine resistance in water and is very useful as an aqueous colorant, and has completed the present invention.
That is, the first subject of the present invention is a dye-complexed clay mineral characterized in that a water-swellable clay mineral is complexed with a nonionic hydrophilic polymer and a water-soluble acidic dye.
In the dye-complexed clay mineral of the present invention, it is preferable that a nonionic hydrophilic polymer and a water-soluble acidic dye are intercalated between the layers of the water-swellable clay mineral.
[0006]
In the present invention, the water-soluble dye is an acid dye .
Moreover, it is preferable that the primary particle diameter of the water-swellable clay mineral is 1 μm or less.
Moreover, the aqueous colorant concerning this invention consists of the said dye composite clay mineral.
The aqueous composition according to the present invention is characterized in that the dye-complexed clay mineral is blended.
The aqueous cosmetic according to the present invention is characterized in that the dye-complexed clay mineral is blended.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
The dye-complexed clay mineral of the present invention is a composite of a water-swellable clay mineral and a nonionic hydrophilic polymer and a water-soluble acidic dye. The hydrophilic hydrophilic polymer and the water-soluble acidic dye are preferably intercalated.
Water-swellable clay minerals generally have a negative surface charge. The acidic dye also has an anionic group such as a SO ₃ ^— group. For this reason, it is usually difficult to intercalate the acid dye between water-swellable clay minerals simply by mixing both in water. Even if the acid dye is adsorbed on the surface of the clay mineral, Easily desorbs.
[0008]
However, by intercalating a nonionic hydrophilic polymer between the layers of the water-swellable clay mineral, the acid dye can be easily intercalated between the layers. This is considered to be because the hydrophilicity between the layers of the water-swellable clay mineral is strengthened by the nonionic hydrophilic polymer and the acid dye is co-adsorbed. Intercalated acid dyes are not easily desorbed by washing .
[0009]
Examples of nonionic hydrophilic polymers used in the present invention include synthetic polymers such as polyvinyl pyrrolidone, polyvinyl alcohol, polyvinyl methyl ether, polyethylene oxide, and ethylene oxide / propylene oxide block copolymers; cellulose and its derivatives, starch and its Examples thereof include polysaccharides such as derivatives. Of these, polyvinyl pyrrolidone and polyvinyl alcohol are preferably used.
[0010]
There are various molecular weights of these nonionic hydrophilic polymers. In the present invention, the molecular weight is not particularly limited as long as the water-soluble dye can be sufficiently included in the clay mineral. However, when the molecular weight of the nonionic hydrophilic polymer used is large when intercalating between the water-swellable clay mineral layers, it is considered that the water-swellable clay mineral tends to aggregate. The average molecular weight is preferably 1,000,000 or less, more preferably 100,000 or less.
When intercalating a nonionic hydrophilic polymer into a water-swellable clay mineral, it is usually used as an aqueous solution having an appropriate concentration.
[0011]
As the water-soluble acidic dye that can be used in the present invention, any water-soluble acid dye can be used as long as it can co-adsorb with a nonionic hydrophilic polymer and be included in the interlayer. Specific examples include red 2, red 3, red 102, red 104-1, red 105-1, red 105-1, red 106, yellow 4, yellow 5, green 3 which are acid dyes. Blue 1, Blue 2, Red 227, Red 230-1, Orange 205, Yellow 202-1, Yellow 203, Green 204, Blue 205, Brown 201, Red 401, Red 504, orange 402, yellow 403-1, yellow 406, yellow 407, green 401. Examples include purple 401 and black 401. Natural acid dyes such as carminic acid and latcaic acid can also be used .
When the water-soluble acid dye is intercalated into the water-swellable clay mineral, it is usually used as an aqueous solution having an appropriate concentration.
[0012]
The water-swellable clay mineral used in the present invention is not particularly limited, but specific examples include layered silicate minerals of the genus smectite, such as montmorillonite, beidellite, nontronite, Saponite, hectorite, etc., which may be either natural or synthetic. Examples of commercially available products include Kunipia, Smecton (Kunimine Industries), Beegum (Vanderbilt), Laponite (Laporte), and Fluorotetrasilicon Mica. In carrying out the present invention, one or two or more of these smectite layered silicates can be arbitrarily selected and used.
[0013]
The water-swellable clay mineral preferably has a primary particle size of 1 micron or less, more preferably 0.5 microns or less.
When intercalating a nonionic hydrophilic polymer or dye, the clay mineral is used in the form of a dispersion dispersed in water at a concentration that does not cause gelation.
[0014]
The dye-complexed clay mineral can be prepared by bringing a water-swellable clay mineral, a nonionic hydrophilic polymer, and an acid dye into contact with each other in water. For example, a water-swellable clay mineral is sufficiently dispersed in water at a concentration (eg, 1 to 5% by mass) that does not cause gelation to prepare an aqueous suspension. This is mixed with a nonionic hydrophilic polymer aqueous solution, and further mixed with a dye aqueous solution. The obtained mixed liquid can be solid-liquid separated (centrifugation, etc.), washed with water, dried and pulverized as necessary to obtain a dye-complexed clay mineral powder. It is also possible to add a dye prior to the nonionic hydrophilic polymer or an aqueous solution in which the nonionic hydrophilic polymer and the dye are mixed in advance to the water-swellable clay mineral water suspension. In the method, a nonionic hydrophilic polymer is first added and sufficiently intercalated, and then a dye is added. It is also possible to powder a water-swellable clay mineral intercalated with a nonionic hydrophilic polymer, and mix the dye with a dispersion obtained by redispersing it in water.
The conditions for mixing the nonionic hydrophilic polymer and the dye with the water-swellable clay mineral may be appropriately determined depending on the raw materials used, but are usually stirring at room temperature for 1 to 24 hours.
[0015]
The dye-complexed clay mineral obtained in the present invention can be used as an aqueous colorant such as a water-soluble dye. When the dye-complexed clay mineral according to the present invention is added to water, it can swell and highly disperse, and can be made into a highly transparent colored aqueous solution, so that it can be used in the same applications as ordinary water-soluble dyes. it can. Moreover, the dye-complexed clay mineral of the present invention is very excellent in chlorine resistance.
Acid dyes have a problem of fading due to chlorine or light. For example, acid dyes such as brown 201 have extremely poor resistance to chlorine, and are simply faded when added to tap water. Other acid dyes are also affected by chlorine and light.
The acidic dye complexed clay mineral of the present invention is very useful as an aqueous colorant because it is excellent in chlorine resistance and has very high color developability and transparency. In addition, improvement in light resistance can be expected.
[0016]
Examples of the colored aqueous composition containing the dye-complexed clay mineral of the present invention include cosmetics having an aqueous phase such as a solubilizing system, an emulsifying system, and a dispersing system. Specifically, skin care cosmetics such as skin lotion, wiping lotion, emulsion, cream and sunscreen, makeup cosmetics such as foundation, rouge and teak can be exemplified. Moreover, it can use without being specifically limited as a coloring agent of an aqueous phase other than cosmetics, for example, a fragrance composition, a cold-retaining agent, a toy, miscellaneous goods, a composition for display, etc. It is also considered effective for coloring artificial rivers and ponds in parks and theme parks.
[0017]
【Example】
Hereinafter, the present invention will be described with reference to specific examples, but the present invention is not limited thereto. In addition, unless otherwise specified, the blending amount is indicated by mass%.
Example 1
4 g of Laponite XLG (manufactured by Laporte, CEC: 66 mequv / 100 g) (La) was added to 250 g of water and sufficiently dispersed in water to obtain a clay water dispersion. 90 g of 17% PVP aqueous solution was added to the clay water dispersion, and the mixture was stirred and mixed at room temperature for 1 day. 50 g of this mixed solution was fractionated, 90 g of a BB aqueous solution containing 1 equivalent of brilliant blue FCF (BB) at a CEC ratio was added, and the mixture was stirred and mixed at room temperature for 1 day. Thereafter, the mixture was centrifuged (18000 rpm × 1.5 h) to obtain a powder of BB-containing clay mineral (BB / PVP / LA-1). The obtained BB / PVP / La-1 was blue.
[0018]
Example 2
4 g of Laponite XLG (manufactured by Laporte, CEC: 66 mequv / 100 g) (La) was added to 250 g of water and sufficiently dispersed in water to obtain a clay water dispersion. 90 g of 17% PVP aqueous solution was added to the clay water dispersion, and the mixture was stirred and mixed at room temperature for 1 day. 50 g of this mixed solution was collected, 90 g of an RB aqueous solution containing 1 equivalent of resorcin brown (RB) at a CEC ratio was added, and the mixture was stirred and mixed at room temperature for 1 day. Then, after centrifugal separation (12000 rpm × 0.5 h) to remove the precipitate once, centrifugal separation (18000 rpm × 1.5 h) was further performed to obtain a powder of RB inclusion clay mineral (RB / PVP / LA-1). The obtained RB / PVP / La-1 was blue.
[0019]
Chlorine resistance The chlorine resistance of the aqueous dispersion of the dye-complexed clay mineral of the present invention was examined.
(Test method)
An aqueous solution in which acid dye RB was added to water having a free chlorine concentration of 0 ppm at a concentration of 0.4 ppm and dissolved therein was used as an RB control. The dye-complexed clay mineral powder of Example 2 was added to and dissolved in water having a free chlorine concentration of 0 ppm so as to give the same color to the control and appearance.
Hydrochloric acid was added to the control and sample solution so that the free chlorine concentration was xppm, and the Lab value was measured before and after the addition of hydrochloric acid (measuring instrument: Gretag Macbeth Color-Eye 7000A). From the measured value, the color difference ΔEX _-0 for the chlorine concentration xppm addition system with respect to the case of 0 ppm chlorine was calculated. A smaller color difference ΔE _X-0 indicates higher chlorine resistance.
The results are shown in Table 1.
[0020]
[Table 1]

[0021]
As is apparent from Table 1, the aqueous solution of the dye-complexed clay mineral (RB / PVP / LA-1) of the present invention has a smaller ΔE _X-0 value than the aqueous solution of the acid dye RB alone. It is understood that it is excellent in chlorination.
Further, as understood from the L value, the aqueous solution of the acid dye-complexed clay mineral of the present invention was almost 100% as in the case of each control, and the transparency was very high. The color development was also very good.
[0022]
Formulation Example 1 Lotion (1) Ion exchange water Residue (2) Ethanol 10
(3) Dipropylene glycol 10
(4) PEG 1500 5
(5) POE (20) oleyl alcohol ether 0.5
(6) Methylcellulose 0.3
(7) Preservative 0.2
(8) Chelating agent 0.01
(9) Perfume appropriate amount (10) BB / PVP / La-1 0.01
[0023]
(Manufacturing method)
3, 4, 6, and 8 were dispersed in a part of 1, and 5, 7, and 9 dissolved in 2 were added thereto. A coloring liquid obtained by dispersing 10 in the residue of 1 and stirring until it became transparent was added to the mixed liquid, toned, and then filtered to obtain a lotion.
[0024]
Formulation Example 2 Latex

[0025]
(Manufacturing method)
A moisturizer part and a preservative are heated and dissolved in a part of ion-exchanged water and a polymer part and dissolved at room temperature. What added the neutralizing agent to this is made into a water phase part. To this, an oil, an antioxidant, and a fragrance that are uniformly mixed at room temperature are added and emulsified using a homomixer. After that, transparent colored water obtained by dispersing tartrazine / PDDA / La in the remaining ion-exchanged water in advance is added to the emulsion, and it is mixed by stirring and mixing, and then degassed and filtered. A milky lotion was obtained.
[0026]
【The invention's effect】
According to the present invention, a dye-complexed clay mineral obtained by combining a water-swellable clay mineral with a nonionic hydrophilic polymer and a water-soluble acidic dye is obtained. It is excellent in properties and chlorine resistance, and is useful as a colorant for aqueous compositions.

Claims (6)

A dye-complexed clay mineral characterized in that a non-ionic hydrophilic polymer and a water-soluble acidic dye are complexed with a water-swellable clay mineral. The dye-complexed clay mineral according to claim 1, wherein a nonionic hydrophilic polymer and a water-soluble acid dye are intercalated between layers of the water-swellable clay mineral. Clay minerals. The dye-complexed clay mineral according to claim 1 or 2, wherein the primary particle diameter of the water-swellable clay mineral is 1 µm or less. An aqueous colorant comprising the dye-complexed clay mineral according to any one of claims 1 to 3 . An aqueous composition comprising the dye-complexed clay mineral according to any one of claims 1 to 3 . An aqueous cosmetic comprising the dye-complexed clay mineral according to any one of claims 1 to 3 .